The global ocean oxygen inventory has decreased by over 2 % since 1960, and the volume of anoxic waters has more than quadrupled over the same time period . This decrease was caused by a decline in oxygen solubility due to higher ocean temperatures , but changes in ocean circulation and biological consumption also contributed to the observed changes . Model simulations project that this decline will continue into the future, although the spatial patterns and magnitude are model-dependent and strongly influenced by the models' ocean diffusivity parameters . Future ocean deoxygenation could eventually pose severe problems for ocean ecosystems and human societies , and there has been a growing interest in recent years to better quantify ocean deoxygenation and understand its drivers.

Ocean oxygenation has also changed in the past. For example, find sulfidic conditions in the near-surface sediments of the Peruvian upwelling area during the Last Interglacial (LIG) period (Marine Isotope Stage (MIS) 5e, ∼ 129–116 kyr ago), based on sedimentary molybdenum accumulation. Records of sedimentary δ15N and redox-sensitive metals show that interglacials in the late Quaternary led to an expansion and/or intensification of near-surface and intermediate-depth suboxic zones in the eastern Pacific margins and the Arabian Sea compared to glacials . These changes in oxygenation have been generally assigned to changes in oxygen supply to the global thermocline . For large regions of the deep ocean this trend was inverted , and deep and bottom waters were better ventilated during interglacials compared to glacials. report close to suboxic conditions during glacial intervals of the past 150 kyr compared to better ventilated conditions during MIS 5e and the Holocene (the past 11 700 years) in the deep subarctic Pacific. In the deep equatorial Pacific there is multi-proxy evidence for reduced oxygen concentrations in all deep Pacific Ocean water masses below 1 km during glacials compared to MIS 5e and the Holocene . Bottom waters in the northern Arabian Sea, on the Portuguese margin, and in the North and South Atlantic, as well as South Atlantic Circumpolar Deep Water (CDW), were also less oxygenated during glacial episodes compared to MIS 5e and the Holocene . It is noteworthy that most reconstructions of ocean oxygenation in the late Quaternary compare glacials with interglacials; there is very little evidence on how oxygen concentrations varied between interglacials. This is an important caveat, as better understanding of ocean oxygen variability in the past, and, in particular, ocean oxygenation during past warm episodes, could inform on the main processes influencing current ocean deoxygenation.

One region with notably large changes in past ocean oxygen concentrations is the semi-enclosed Mediterranean Sea, where there is evidence of intervals with severe anoxia during past interglacials . These intervals are characterized by sediment layers with elevated organic carbon concentrations (sapropels) and coincide with astronomically timed episodes of monsoon intensification, causing enhanced runoff from North Africa into the Mediterranean Sea and leading to stratification . The resulting anoxia was often more intensely developed in the eastern Mediterranean than in the western Mediterranean.

Here, we analyze simulations integrated with the Australian earth system model ACCESS-ESM1.5 for two interglacials, MIS 5e, or the Last Interglacial (LIG), and MIS 9e. The LIG is an interesting time period because it was globally the warmest interglacial of the past 800 kyr . Being the most recent interglacial, the spatial and temporal resolution of climate proxies is also much better than for earlier interglacials. The LIG climate has been recently simulated by a variety of climate models under the Paleoclimate Model Intercomparison Project 4 (PMIP4) lig127k experiment .

MIS 9e (∼ 336–321 kyr ago) stands out by its high greenhouse gas forcing, with the highest carbon dioxide and methane concentrations over the past 800 kyr . It is also one of the three interglacials (together with MIS 11 and MIS 17) with the lowest value of seawater δ18O, which might imply high sea levels and small continental ice volumes , although sea-level records from the Red Sea show that MIS 5e had higher sea levels than MIS 9e . MIS 9e was an exceptionally short interglacial with the warmest temperatures in Antarctica over the past 800 kyr . We will focus on how changes in orbital parameters and greenhouse gas concentrations influenced simulated ocean oxygenation for these two interglacials.

This paper is structured as follows. Section  describes the model, the experimental setup, and the time series for each of the analyzed experiments. Section  first analyses changes in large-scale circulation patterns and oxygenation and then focuses on changes in the Mediterranean Sea. In Sect.  we discuss uncertainties and situate our results within a broader context. Section  summarizes the main results.

We use the Australian Community Climate and Earth System Simulator Earth System Model, ACCESS-ESM1.5 , to integrate three equilibrium simulations under preindustrial, MIS 5e, and MIS 9e boundary conditions. The model includes the atmosphere UK Met Office Unified Model (UM) version 7.3 , the Community Atmosphere Biosphere Land Exchange model (CABLE) version 2.4 , the NOAA/GFDL Modular Ocean Model (MOM) version 5 , and the Los Alamos National Laboratory sea ice model (LANL CICE) version 4.1 . The components communicate with each other through the Ocean Atmosphere Sea Ice Soil Model Coupling Toolkit (OASIS-MCT; ). The land and atmosphere components have a horizontal resolution of 1.875° × 1.25°, with 38 vertical levels for the atmosphere model. The ocean and sea ice components have a resolution of 1° × 1°, with 50 vertical levels for the ocean model. The horizontal resolution of the ocean model is higher near the Equator (0.33°) and in the Southern Ocean (∼ 0.4° at 70° S). Ocean biogeochemistry is represented by the Whole Ocean Model of Biogeochemistry And Trophic-dynamics (WOMBAT; ).

WOMBAT is a nutrient–phytoplankton–zooplankton–detritus (NPZD) model . It includes one functional type of phytoplankton and zooplankton. As prognostic tracers it simulates dissolved inorganic carbon (DIC), alkalinity (ALK), phosphate (PO₄), oxygen (O₂), and iron. The stoichiometry is fixed at a C : N : P : O₂ ratio of 106 : 16 : 1 : -172. CaCO₃ export from the photic zone is set at ∼ 8 % of the organic carbon export. Detrital decomposition is a function of temperature and is allowed to occur when oxygen is zero. Even though nitrification and denitrification are not explicitly included in the model and the global nitrogen budget is kept constant , this formulation emulates the effect of denitrification. The dissolution of CaCO₃ occurs at a constant rate. All organic and inorganic particles reaching the bottom are remineralized, given that ACCESS-ESM1.5 does not include burial of sediments.

The preindustrial 1850 equilibrium simulation (PI) is integrated following the CMIP6 protocol with the exception of using the CMIP5 solar constant (1365.65 W m⁻²). The MIS 5e simulation (LIG) is integrated following the PMIP4 protocol with the solar constant of CMIP5-PMIP3 (1365.65 W m⁻²). Both PI and LIG simulations have been evaluated extensively in the recent literature .

The MIS 9e simulation was set up with boundary conditions corresponding to 333 ka and the same solar constant as for PI and LIG (see Table ). The Greenland and Antarctic ice sheets and vegetation distribution are the same in all three simulations, but the leaf area index is calculated prognostically. Anomalies in incoming solar radiation are shown in Fig. .

Dissolved oxygen is a tracer with very long equilibration times. Figure  shows time series of dissolved oxygen for the three simulations analyzed in this study. While oxygen concentrations have reached quasi-equilibrium for North Atlantic Deep Water (NADW), in the intermediate waters of the North Pacific, and in Antarctic Bottom Water (AABW) south of 35° S in all runs, there is still a slight drift in global mean dissolved oxygen in our LIG and MIS 9e simulations and a more substantial drift in the Mediterranean Sea.

In Sect.  we partition changes in dissolved oxygen into two components, changes in the saturated concentration of oxygen O2sat and changes in apparent oxygen utilization (AOU). AOU estimates the oxygen consumed during respiration and can be calculated as the difference between dissolved oxygen concentration (O₂) and O2sat: 1AOU=O2sat(T,S)-O2, where T is the potential temperature and S salinity. Changes in AOU are therefore a combination of changes in circulation (with sluggish water masses tending to have higher AOU) and changes in remineralization rates, which depend on the vertical export of organic matter (export production) and temperature. Please note that the here used metric AOU assumes that dissolved oxygen in surface waters is in equilibrium with the atmosphere, which might lead to an overestimation of the true oxygen utilization (TOU) .

The oxygenation of the world's oceans is very similar in our LIG and MIS 9e simulations and quite different compared to our PI simulation. These differences are primarily due to circulation changes and changes in export production and secondarily due to the solubility effect. The large-scale ocean circulation patterns, including AABW, NADW, and the ventilation of the North Pacific Ocean, are therefore very sensitive to the latitudinal and seasonal distribution of incoming solar radiation in the ACCESS ESM1.5 and less sensitive to changes in greenhouse gas concentrations within the range of these three interglacials. The insolation anomalies are indeed quite similar for LIG and MIS 9e (Fig. ), while the greenhouse gas forcing is highest for MIS 9e and lowest for LIG, with PI being in the middle (Table ).

While quantitative records of past oxygenation are difficult to reconstruct with proxies , qualitative records exist. For the more recent Pleistocene period, most records looking at past ocean oxygenation have focused on glacial–interglacial variations; for summaries see and . used epibenthic foraminifera carbon isotopes to make inferences of intermediate water ventilation and oxygenation in the northeast Pacific and suggested that waters above 2000 m depth were less oxygenated during MIS 5e. If the proposed relationship between benthic foraminifera carbon isotopes and apparent oxygen utilization holds, then overall reduced carbon isotopes during MIS 5e would imply an overall decrease in global ocean oxygenation, agreeing with our simulations. There is also evidence for reduced AABW formation and a decrease in dissolved oxygen in the Southern Ocean based on redox elements .

Oxygen minimum zones (OMZs) have expanded and contracted repeatedly in the past in response to global changes in climate . To the authors' knowledge, there is no global modeling study analyzing the extent and magnitude of OMZs during MIS 5e and MIS 9e. Simulating OMZs with earth system models is very challenging, because low oxygen concentrations are the result of a subtle balance between two large opposing processes: the physical transport of oxygen-rich waters into the region of interest and the local flux of particulate matter and remineralization. Climate models are not very skilled in representing these dynamics, mostly because their resolution does not resolve equatorial dynamics well enough. Another problem is the simple representation of biology and geochemistry in the majority of current state-of-the-art models. The ACCESS ESM1.5 is not an exception. While the extent of the OMZs in the tropical Pacific is reasonably well represented, there are deficits in other regions. Our results show that relatively small changes in circulation, such as the subtle increase in ventilation of the upper North Pacific Ocean in our LIG and MIS 9e simulations, can have a significant impact on oxygen concentrations, emphasizing the need of a realistic representation of physical circulation when simulating oxygen. For example, cores LV-28-44-3 (52°02.514^′ N, 153°05.949^′ E; 684 m) in the eastern Sea of Okhotsk and MR0604-PC07A (51°16^′56^′′​​​​​​​ N, 149°12^′60^′′​​​​​​​ E; 1247 m) in the central Sea of Okhotsk recorded intervals of suboxic conditions during MIS 5e. While our simulation points to suboxic waters east of the Kamchatka Peninsula, the waters west of the peninsula are well oxygenated (Fig. ). It should be noted that these cores were retrieved from a semi-isolated marginal basin and are influenced by small-scale local circulation patterns that are not well resolved in the ACCESS ESM1.5.

We find that the main Eastern Boundary Upwelling Systems in the North Pacific and Atlantic Oceans are weaker in the LIG and MIS 9e simulations compared to PI. This is consistent with high sea surface temperatures and faunal composition off the Canary Islands during MIS 5e and microfossil assemblages from MIS 5e off the coast of northern California . However, Si / Ti, Cd / Al, and Ni / Al records from core MD02-2508 (23°27.91^′ N, 111°35.74^′ W; 606 m) suggest that biological productivity was high during MIS 5e further south, off the coast of Baja California , which is contrary to our results, although some upwelling is still present in our LIG and MIS 9e simulations. Coastal upwelling may have been similar or enhanced during MIS 5e and MIS 9e along the southeast African margin , expanded along the Brazil margin during MIS 5e , and increased at higher latitudes during MIS 5e and MIS 9e . This agrees broadly with the simulated patterns of detrital organic carbon concentration anomalies.

The Mediterranean's sedimentary record is punctuated by periodic deep-sea anoxic events that manifest themselves in layers with elevated organic carbon concentrations (sapropels) and are strongly associated with times of African monsoon intensification. We find monsoon intensification in our LIG and MIS 9e simulations, enhanced river runoff, and a freshening of the surface layers of the Mediterranean Sea. The resulting vertical stratification leads to anoxic conditions in the east Mediterranean Sea in our LIG simulation and hypoxic conditions in our MIS 9e simulation. The Tyrrhenian Sea is anoxic in both simulations, and the west Mediterranean shows an east–west gradient of oxygenation that is qualitatively in agreement with sediment data. It should be noted, however, that the ACCESS ESM1.5 is a global model with relatively coarse horizontal resolution (1° × 1° in the Mediterranean Sea). Such coarse-resolution model cannot be expected to simulate Mediterranean circulation skillfully. There are three main sites of deep water formation in the Mediterranean Sea in today's climate. Western Mediterranean deep water is formed during winter in the Gulf of Lion. Eastern Mediterranean deep water formation occurs in two sites, the Adriatic Sea, where bottom water is formed in winter and exits through the Strait of Otranto, and the Rhodes Gyre in the Levantine Basin. In our PI simulation, the main deep water formation occurs in the Ionian Sea, and to a lesser extent in the southern Adriatic Sea and east of the Gulf of Lion. Our results should therefore be taken as a qualitative indication of enhanced stratification and oxygen loss without putting too much trust into simulated regional changes. For example, find shallow water euxinia during S5 on the Adriatic Shelf due to a shutdown of North Adriatic Dense Water formation. This region remains well ventilated in our simulations. In addition, note that Mediterranean oxygen content is still drifting in our LIG and MIS 9e runs. As a result, MIS 9e could reach an oxygen loss similar to LIG on a longer timescale (Fig. ).

Our study shows that even relatively small changes in boundary conditions can lead to large changes in ocean circulation, upwelling systems, export production, and ocean oxygenation. While our results cannot directly inform on future changes in ocean oxygenation, there might be some similarities. Ocean temperatures and ocean stratification are projected to continue to increase until atmospheric CO₂ concentrations finally plateau. Current ocean deoxygenation is therefore not easily reversible and will persist for centuries . There will be physiological and morphological impacts on organisms, including reduced growth for a vast range of taxonomic groups . Exposure to low-oxygen conditions has also been associated with a delay in when fish produce eggs, a reduction of the number of eggs fish produce, and blindness . The metabolic demand of oxygen increases with water temperature, and when combined with deoxygenation, this can lead to respiratory distress, followed by respiratory failure and death . Over 50 mass mortality events due to hypoxia have been recorded in the tropics to date . The consequences of deoxygenation for fisheries and the world's future food supply could thus be serious .

Here we perform a snapshot experiment of the peak LIG and MIS 9e climates with a single model. These simulations thus only represent an equilibrium response to peak interglacial conditions and do not represent potential transient climatic changes associated with the end of deglaciations or abrupt climate changes linked to continental ice-sheet melting. In addition, the dissolved O₂ content simulated in these experiments is very dependent on the simulated oceanic circulation. The state of the ocean circulation during these interglacials is, however, unclear. Transient simulations through whole interglacial and multi-model intercomparisons would be preferable and give a better indication of the robustness and uncertainties of past oxygenation patterns and their variability . We hope that other modeling groups will consider analyzing ocean oxygenation during past interglacials. Oxygen concentration is a variable with extremely long equilibration times, so caution should be taken when climate models are not integrated for at least 1000 years, preferably longer, and the drift in the deep ocean is still significant.

We integrated three equilibrium simulations with Australia's earth system model ACCESS ESM1.5 under preindustrial (PI), Last Interglacial (LIG, 127 ka), and MIS 9e (333 ka) boundary conditions. The LIG and MIS 9e simulations show similar anomalies in large-scale oxygenation pointing to the fact that circulation patterns and oxygen concentrations are more sensitive to the distribution of incoming solar radiation than to greenhouse gas concentrations within the range of these three interglacials. Antarctic Bottom Water (AABW) is weaker and warmer, leading to deoxygenation mostly due to higher oxygen utilization and, to a lesser extent, the solubility effect. North Atlantic Deep Water (NADW) is overall cooler and better ventilated, leading to higher in situ oxygen concentrations. Water masses in the upper 2000 m of the North Pacific are both warmer and higher in oxygen content, due to enhanced subduction in the Bering Sea and a reduction in export production off the coast of North America. These anomalies are more pronounced in the MIS 9e simulation than in the LIG simulation, with the exception of the North Pacific Ocean, where the oxygenation anomaly is strongest in the LIG simulation. While the global ocean is overall less oxygenated in MIS 9e and LIG compared to PI, the volume of suboxic and anoxic waters is smaller in MIS 9e and LIG, mainly due to the oxygenation of the North Pacific Ocean. The Mediterranean Sea is the exception, where oxygen is significantly more depleted in MIS 9e and LIG compared to PI, due to an intensification and expansion of the African monsoon, enhanced runoff, and resulting freshening of surface waters and stratification. In the LIG simulation, 30 % of the total seawater volume in the Mediterranean Sea is anoxic (< 1 mm m⁻³) and 63 % is hypoxic (< 62 mm m⁻³). This deoxygenation is not quite as pronounced in the MIS 9e simulation with 6 % of anoxic waters and 34 % of hypoxic waters. Dissolved oxygen concentrations are still drifting in both simulations, even after integration times of well over 1500 years.

The simulation of ocean oxygen concentrations is challenging, as oxygen levels depend on complex physical and biogeochemical processes that must be represented correctly in a climate model to simulate oxygen realistically. State-of-the-art earth system climate models systematically underestimate the observed rates of oxygen loss and are also not very skillful in reproducing the observed patterns of deoxygenation . In this study, we confirmed that subtle changes in ocean circulation can have significant impact on oxygen concentrations. For trustworthy future projections, high-resolution ocean models are therefore needed to represent the relevant ocean circulation patterns as well as possible, but these models are computationally expensive. Oceanic oxygen takes centuries to adjust, and we currently lack computer power to run high-resolution models for the timescales needed for initialization and equilibrium responses. Another important challenge is the representation of biogeochemical processes in models, as our knowledge of coupled biogeochemical processes is still incomplete.